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Online since: September 2013
Authors: Hong Zhang, Wei Hua, Qing Ding Wu
Fig. 9 Fracture morphology of warm compacted CSP/Al composite materials
Conclusions
Warm compacted CSP/Al composite materials and related sliding bearings products mentioned here were prepared employing new technology of wood powder warm compacted formation which was developed based on wood science, ceramimetrallurgy and other inter-disciplines of materials forming theory.
Xiang et al: Chinese Journal of Spectroscopy Laboratory.
Wu: New Building Materials.
Yi: Journal of Chongqing Jiaotong University(Natural Science).
Martins: Journal of materials processing technology, Vol. 101(2000), p. 52-63.
Xiang et al: Chinese Journal of Spectroscopy Laboratory.
Wu: New Building Materials.
Yi: Journal of Chongqing Jiaotong University(Natural Science).
Martins: Journal of materials processing technology, Vol. 101(2000), p. 52-63.
Online since: July 2011
Authors: Yan Jin Shi, Yan Feng
Various oil-absorbing materials are introduced.
The limitations of the new oil-absorbing materials are pointed.
Conclusions Compared with the traditional oil-absorbing materials, new oil-absorbing materials overcome the limitations of traditional oil-absorbing materials.
[7] Biao Huang: Journal of Nanjing Forestry University (Natural Sciences Edition), Vol. 28 (2004), p.82, in Chinese
[26] Xiuqi Liu, Guo Zhang, Heqin Xing, Jing Jin: Materials Science & Technology, Vol. 17(2009), p. 816-820, in Chinese
The limitations of the new oil-absorbing materials are pointed.
Conclusions Compared with the traditional oil-absorbing materials, new oil-absorbing materials overcome the limitations of traditional oil-absorbing materials.
[7] Biao Huang: Journal of Nanjing Forestry University (Natural Sciences Edition), Vol. 28 (2004), p.82, in Chinese
[26] Xiuqi Liu, Guo Zhang, Heqin Xing, Jing Jin: Materials Science & Technology, Vol. 17(2009), p. 816-820, in Chinese
Online since: April 2015
Authors: Hsiu Lu Chiang, Tsu Liang Chou, Tze Chi Hsu, Jing Hong Chen
Surface roughness and magnetic effect of magnetized journal bearings lubricated with ferrofluid
Tze-Chi Hsu1, a, Jing-Hong Chen2, b, Tsu-Liang Chou3, Hsin-Lu Chiang3
1Department of Mechanical Engineering, Yuan-Ze Unversity, Chung-Li 320, Taiwan, ROC
2National Chung-Shan Institute of Science & Technology, P.O.
Ferrofluids are widely applied in bearing systems due to their unique characteristics possessing both the powerful magnetism of solid magnetic materials as well as the liquidity of fluids [1-4].
When λ<0.6, the surface roughness behavior of the journal bearing is similar to the short journal bearing.
When λ>1.8, the surface roughness behavior of the journal bearing is similar to the long journal bearing.
Journal of marine science and technology, Vol.22(2014), No. 2, p. 154-162
Ferrofluids are widely applied in bearing systems due to their unique characteristics possessing both the powerful magnetism of solid magnetic materials as well as the liquidity of fluids [1-4].
When λ<0.6, the surface roughness behavior of the journal bearing is similar to the short journal bearing.
When λ>1.8, the surface roughness behavior of the journal bearing is similar to the long journal bearing.
Journal of marine science and technology, Vol.22(2014), No. 2, p. 154-162
Online since: July 2011
Authors: Guang Yong Wu, Yong Lian Zhang, Chong Hai Xu, Ming Dong Yi, Bin Fang
Parks, Modelling studies applied to functionally graded materials, Journal of Mater Sci.. 30 (1995) 183-219
Ge, Design and fabrication of S-Type B4C-SiC/C functionally graded materials, Journal of University of Science and Technology Beijing. 22 (2000) 166-169 (In Chinese)
Parks, Modelling studies applied to functionally graded materials, Journal of Materials Science. 30 (1995) 2183-2193
Han, Optimum design of TiC-Ni functionally graded materials, Material Science and Technology. 8 (2000) 81-83 (In Chinese)
Jie, Finite element design of MgO/Ni system functionally graded materials, Journal of Materials Processing Technology. 182 (2007) 181-184
Ge, Design and fabrication of S-Type B4C-SiC/C functionally graded materials, Journal of University of Science and Technology Beijing. 22 (2000) 166-169 (In Chinese)
Parks, Modelling studies applied to functionally graded materials, Journal of Materials Science. 30 (1995) 2183-2193
Han, Optimum design of TiC-Ni functionally graded materials, Material Science and Technology. 8 (2000) 81-83 (In Chinese)
Jie, Finite element design of MgO/Ni system functionally graded materials, Journal of Materials Processing Technology. 182 (2007) 181-184
Online since: January 2016
Authors: Sergey A. Aksenov, Ivan Y. Zakhariev, Aleksey V. Kolesnikov, Sergey A. Osipov
Munirova, Mechanical modelling of the universal superplastic curve, Journal of Materials Science 35 (2000) 2455 – 2466
Khraisheh, A new combined experimental–numerical approach to evaluate formability of rate dependent materials, International Journal of Mechanical Sciences 66 (2013) 55-66
Chang, Material Models for Simulation of Superplastic Mg Alloy Sheet Forming, Journal of Materials Engineering and Performance 19(4) (2010) 488-494
Liew, Three-dimensional modeling and simulation of superplastic forming, Journal of Materials Processing Technology 150 (2004) 76–83
Jun, A Mechanical Analysis of the Superplastic Free Bulging of Metal Sheet, Materials Science and Engineering 84 (1986), 111-125
Khraisheh, A new combined experimental–numerical approach to evaluate formability of rate dependent materials, International Journal of Mechanical Sciences 66 (2013) 55-66
Chang, Material Models for Simulation of Superplastic Mg Alloy Sheet Forming, Journal of Materials Engineering and Performance 19(4) (2010) 488-494
Liew, Three-dimensional modeling and simulation of superplastic forming, Journal of Materials Processing Technology 150 (2004) 76–83
Jun, A Mechanical Analysis of the Superplastic Free Bulging of Metal Sheet, Materials Science and Engineering 84 (1986), 111-125
Online since: May 2011
Authors: Yun Wang
Outlook
New starch-based architectural gelled materials have fairly vast application prospects in three aspects below:
Architectural gelled materials for civil architecture.
Journal of Xinjiang University(Natural Science Edition) .2010,Vol.27,No.176-80 [4] Fanta G F, Felker F C, Salch JH.
Journal of Applied Polymer Science.2003, 89: 3323-332 [5] Xiao-qing Huang, Guang-liang Li, Wei-qin Zhu.
Journal of Northwest Minorities University(Natural Science).2000, Vol.21 No.3:21-22 [13] Peng Xu,Xiao-dong Shen,Bai-qian Zhong.
Journal of South China University of Technology(Natural Science Edition). 2005,Vol.l33 No.6:74-78 [18] Chen-hui Ju,Jian-dong Ye,Xian-liang Song,et al.
Journal of Xinjiang University(Natural Science Edition) .2010,Vol.27,No.176-80 [4] Fanta G F, Felker F C, Salch JH.
Journal of Applied Polymer Science.2003, 89: 3323-332 [5] Xiao-qing Huang, Guang-liang Li, Wei-qin Zhu.
Journal of Northwest Minorities University(Natural Science).2000, Vol.21 No.3:21-22 [13] Peng Xu,Xiao-dong Shen,Bai-qian Zhong.
Journal of South China University of Technology(Natural Science Edition). 2005,Vol.l33 No.6:74-78 [18] Chen-hui Ju,Jian-dong Ye,Xian-liang Song,et al.
Online since: July 2024
Authors: Asif Javed Sidiqui, Mohd Gulam Waris Khan
This paper highlights the dynamic field of polymer science in shoe design and manufacturing by examining the latest developments in polymer materials for footwear applications.
Footwear Materials There are various types of materials used in footwear.
(Ed.), The Science of Footwear (1st ed.).
Production.Res., 45 (18), 4403–4422. (2007) [9] Martinez, L. et al., Polymeric Coatings for Footwear: Advances and Applications, Journal of Applied Polymer Science. (2020) [10] Taylor, R. et al., Functionalized Polymers for Enhanced Performance in Footwear, Polymer Composites. (2019) [11] Brown, M. et al., Innovative Polymer Materials for Next-Generation Footwear: A Comprehensive Review, Materials Today Chemistry. (2019) [12] Report by BATA.
Page (11-20). (2014) [14] Johnson, A. et al., Recent Advances in Polymer Blends for Sustainable Footwear, Polymer Engineering & Science. (2021) [15] White, S. et al., Polymer Foams in Footwear: Current Trends and Future Prospects, Polymer Testing. (2022) [16] Khan M.G.W.and Faheem A., Vulcanization, compounding, thermo-mechanical properties and surface morphology of montmorillonite nanoclay based nitrile rubber nanocomposites”, Materials Today: Proceedings, Elsevier, 2214-7853, (2023) [17] Smith J. et al., Polymer Nanocomposites for Footwear Applications: A Review, Journal of Polymer Science: Part B: Polymer Physics. (2020) [18] Clark, H. et al., Polymer Nanofibers for Lightweight and Durable Footwear, Materials Science and Engineering. (2018) [19] S.
Footwear Materials There are various types of materials used in footwear.
(Ed.), The Science of Footwear (1st ed.).
Production.Res., 45 (18), 4403–4422. (2007) [9] Martinez, L. et al., Polymeric Coatings for Footwear: Advances and Applications, Journal of Applied Polymer Science. (2020) [10] Taylor, R. et al., Functionalized Polymers for Enhanced Performance in Footwear, Polymer Composites. (2019) [11] Brown, M. et al., Innovative Polymer Materials for Next-Generation Footwear: A Comprehensive Review, Materials Today Chemistry. (2019) [12] Report by BATA.
Page (11-20). (2014) [14] Johnson, A. et al., Recent Advances in Polymer Blends for Sustainable Footwear, Polymer Engineering & Science. (2021) [15] White, S. et al., Polymer Foams in Footwear: Current Trends and Future Prospects, Polymer Testing. (2022) [16] Khan M.G.W.and Faheem A., Vulcanization, compounding, thermo-mechanical properties and surface morphology of montmorillonite nanoclay based nitrile rubber nanocomposites”, Materials Today: Proceedings, Elsevier, 2214-7853, (2023) [17] Smith J. et al., Polymer Nanocomposites for Footwear Applications: A Review, Journal of Polymer Science: Part B: Polymer Physics. (2020) [18] Clark, H. et al., Polymer Nanofibers for Lightweight and Durable Footwear, Materials Science and Engineering. (2018) [19] S.
Online since: November 2024
Authors: Syed Mohammed Saad, Ahmed Ibrahim Mohammed Al Hashmi, Qusai Said Nasser Alshaaibi, Abdullah A.K. Al-Maskari
Located in the Material Science laboratory within the Mechanical Engineering Department at UTAS – Ibra, this versatile instrument is employed to assess the hardness of materials.
References [1] Engineering Materials.
Springer, Cham. https://doi.org/10.1007/978-3-319-01815-7_25 [3] Munonyedi Kelvin Egbo,A fundamental review on composite materials and some of their applications in biomedical engineering,Journal of King Saud University - Engineering Sciences, Volume 33, Issue 8,2021,Pages 557-568, ISSN 1018-3639
Iraqi Journal of Science, 1960-1970
Journal of Mechanical Engineering and Sciences, 13(4), 5961-5972
References [1] Engineering Materials.
Springer, Cham. https://doi.org/10.1007/978-3-319-01815-7_25 [3] Munonyedi Kelvin Egbo,A fundamental review on composite materials and some of their applications in biomedical engineering,Journal of King Saud University - Engineering Sciences, Volume 33, Issue 8,2021,Pages 557-568, ISSN 1018-3639
Iraqi Journal of Science, 1960-1970
Journal of Mechanical Engineering and Sciences, 13(4), 5961-5972
Online since: September 2013
Authors: Qiu Feng Li, Yu Wang, Lu Ying Xi
Research on Ultrasonic Testing of Coarse-Grain Materials with Hilbert-Huang Transform
Li Qiufenga, Wang Yu, Xi Luying
Key Laboratory of Nondestructive Testing (Nanchang Hangkong University), Ministry of Education, Nanchang, 330063, China
aqiufenglee@163.com
Keywords: Coarse-grain materials, UT, IMF, Marginal spectrum
Abstract.
Coarse-grained materials are used more and more widely in modern industry.
And however there are some difficulties in ultrasonic NDT of coarse-grained materials, and the major reasons are as followed.
Metallurgical and Materials Transactions A: Physical Metallurgy and Materials Science, 2011, v42, n3, pp: 543-547
Journal of Changchun University of Technology (Natural Science Edition), 2012, v33, n1, pp: 7-10
Coarse-grained materials are used more and more widely in modern industry.
And however there are some difficulties in ultrasonic NDT of coarse-grained materials, and the major reasons are as followed.
Metallurgical and Materials Transactions A: Physical Metallurgy and Materials Science, 2011, v42, n3, pp: 543-547
Journal of Changchun University of Technology (Natural Science Edition), 2012, v33, n1, pp: 7-10
Online since: April 2022
Authors: Srungarpu Nagabhusan Achary, Sravan Bokka, Anirban Chowdhury
[3] Bajaj, P., Fire-retardant materials, Bulletin of Materials Science, 15 (1992) 67-76
Kumar, Structural, thermal, dielectric studies on sol–gel derived MgO from non-alkoxide route, Materials science and technology, 22 (2006) 1249-1254
Wilkie, Fire retardancy and morphology of layered double hydroxide nanocomposites: a review, Journal of Materials Chemistry, 22 (2012) 18701
[60] Maitra, S., et al., Effect of compaction on the kinetics of thermal decomposition of dolomite under non-isothermal condition, Journal of Materials Science, 40 (2005) 4749-4751
Levchik, A review of current flame retardant systems for epoxy resins, Journal of fire sciences, 22 (2004) 25-40
Kumar, Structural, thermal, dielectric studies on sol–gel derived MgO from non-alkoxide route, Materials science and technology, 22 (2006) 1249-1254
Wilkie, Fire retardancy and morphology of layered double hydroxide nanocomposites: a review, Journal of Materials Chemistry, 22 (2012) 18701
[60] Maitra, S., et al., Effect of compaction on the kinetics of thermal decomposition of dolomite under non-isothermal condition, Journal of Materials Science, 40 (2005) 4749-4751
Levchik, A review of current flame retardant systems for epoxy resins, Journal of fire sciences, 22 (2004) 25-40